test/support/test_allocator.h - LeafOS-Project/android_external_libcxx - Gitiles

 //===----------------------------------------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is dual licensed under the MIT and the University of Illinois Open
 // Source Licenses. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #ifndef TEST_ALLOCATOR_H
 #define TEST_ALLOCATOR_H

 #include <cstddef>
 #include <type_traits>
 #include <cstdlib>
 #include <new>
 #include <climits>
 #include <cassert>

 #include "test_macros.h"

 class test_alloc_base
 {
 protected:
     static int time_to_throw;
 public:
     static int throw_after;
     static int count;
     static int alloc_count;
 };

 int test_alloc_base::count = 0;
 int test_alloc_base::time_to_throw = 0;
 int test_alloc_base::alloc_count = 0;
 int test_alloc_base::throw_after = INT_MAX;

 template <class T>
 class test_allocator
     : public test_alloc_base
 {
     int data_;

     template <class U> friend class test_allocator;
 public:

     typedef unsigned                                                   size_type;
     typedef int                                                        difference_type;
     typedef T                                                          value_type;
     typedef value_type*                                                pointer;
     typedef const value_type*                                          const_pointer;
     typedef typename std::add_lvalue_reference<value_type>::type       reference;
     typedef typename std::add_lvalue_reference<const value_type>::type const_reference;

     template <class U> struct rebind {typedef test_allocator<U> other;};

     test_allocator() throw() : data_(0) {++count;}
     explicit test_allocator(int i) throw() : data_(i) {++count;}
     test_allocator(const test_allocator& a) throw()
         : data_(a.data_) {++count;}
     template <class U> test_allocator(const test_allocator<U>& a) throw()
         : data_(a.data_) {++count;}
     ~test_allocator() throw() {assert(data_ >= 0); --count; data_ = -1;}
     pointer address(reference x) const {return &x;}
     const_pointer address(const_reference x) const {return &x;}
     pointer allocate(size_type n, const void* = 0)
         {
             assert(data_ >= 0);
             if (time_to_throw >= throw_after) {
 #ifndef _LIBCPP_NO_EXCEPTIONS
                 throw std::bad_alloc();
 #else
                 std::terminate();
 #endif
             }
             ++time_to_throw;
             ++alloc_count;
             return (pointer)::operator new(n * sizeof(T));
         }
     void deallocate(pointer p, size_type)
         {assert(data_ >= 0); --alloc_count; ::operator delete((void*)p);}
     size_type max_size() const throw()
         {return UINT_MAX / sizeof(T);}
 #if TEST_STD_VER < 11
     void construct(pointer p, const T& val)
         {::new(static_cast<void*>(p)) T(val);}
 #else
     template <class U> void construct(pointer p, U&& val)
         {::new(static_cast<void*>(p)) T(std::forward<U>(val));}
 #endif
     void destroy(pointer p)
         {
             p->~T();
             ((void)p); // Prevent MSVC's spurious unused warning
         }
     friend bool operator==(const test_allocator& x, const test_allocator& y)
         {return x.data_ == y.data_;}
     friend bool operator!=(const test_allocator& x, const test_allocator& y)
         {return !(x == y);}
 };

 template <class T>
 class non_default_test_allocator
     : public test_alloc_base
 {
     int data_;

     template <class U> friend class non_default_test_allocator;
 public:

     typedef unsigned                                                   size_type;
     typedef int                                                        difference_type;
     typedef T                                                          value_type;
     typedef value_type*                                                pointer;
     typedef const value_type*                                          const_pointer;
     typedef typename std::add_lvalue_reference<value_type>::type       reference;
     typedef typename std::add_lvalue_reference<const value_type>::type const_reference;

     template <class U> struct rebind {typedef non_default_test_allocator<U> other;};

 //    non_default_test_allocator() throw() : data_(0) {++count;}
     explicit non_default_test_allocator(int i) throw() : data_(i) {++count;}
     non_default_test_allocator(const non_default_test_allocator& a) throw()
         : data_(a.data_) {++count;}
     template <class U> non_default_test_allocator(const non_default_test_allocator<U>& a) throw()
         : data_(a.data_) {++count;}
     ~non_default_test_allocator() throw() {assert(data_ >= 0); --count; data_ = -1;}
     pointer address(reference x) const {return &x;}
     const_pointer address(const_reference x) const {return &x;}
     pointer allocate(size_type n, const void* = 0)
         {
             assert(data_ >= 0);
             if (time_to_throw >= throw_after) {
 #ifndef _LIBCPP_NO_EXCEPTIONS
                 throw std::bad_alloc();
 #else
                 std::terminate();
 #endif
             }
             ++time_to_throw;
             ++alloc_count;
             return (pointer)::operator new (n * sizeof(T));
         }
     void deallocate(pointer p, size_type)
         {assert(data_ >= 0); --alloc_count; ::operator delete((void*)p); }
     size_type max_size() const throw()
         {return UINT_MAX / sizeof(T);}
 #if TEST_STD_VER < 11
     void construct(pointer p, const T& val)
         {::new(static_cast<void*>(p)) T(val);}
 #else
     template <class U> void construct(pointer p, U&& val)
         {::new(static_cast<void*>(p)) T(std::forward<U>(val));}
 #endif
     void destroy(pointer p) {p->~T();}

     friend bool operator==(const non_default_test_allocator& x, const non_default_test_allocator& y)
         {return x.data_ == y.data_;}
     friend bool operator!=(const non_default_test_allocator& x, const non_default_test_allocator& y)
         {return !(x == y);}
 };

 template <>
 class test_allocator<void>
     : public test_alloc_base
 {
     int data_;

     template <class U> friend class test_allocator;
 public:

     typedef unsigned                                                   size_type;
     typedef int                                                        difference_type;
     typedef void                                                       value_type;
     typedef value_type*                                                pointer;
     typedef const value_type*                                          const_pointer;

     template <class U> struct rebind {typedef test_allocator<U> other;};

     test_allocator() throw() : data_(0) {}
     explicit test_allocator(int i) throw() : data_(i) {}
     test_allocator(const test_allocator& a) throw()
         : data_(a.data_) {}
     template <class U> test_allocator(const test_allocator<U>& a) throw()
         : data_(a.data_) {}
     ~test_allocator() throw() {data_ = -1;}

     friend bool operator==(const test_allocator& x, const test_allocator& y)
         {return x.data_ == y.data_;}
     friend bool operator!=(const test_allocator& x, const test_allocator& y)
         {return !(x == y);}
 };

 template <class T>
 class other_allocator
 {
     int data_;

     template <class U> friend class other_allocator;

 public:
     typedef T value_type;

     other_allocator() : data_(-1) {}
     explicit other_allocator(int i) : data_(i) {}
     template <class U> other_allocator(const other_allocator<U>& a)
         : data_(a.data_) {}
     T* allocate(std::size_t n)
         {return (T*)::operator new(n * sizeof(T));}
     void deallocate(T* p, std::size_t)
         {::operator delete((void*)p);}

     other_allocator select_on_container_copy_construction() const
         {return other_allocator(-2);}

     friend bool operator==(const other_allocator& x, const other_allocator& y)
         {return x.data_ == y.data_;}
     friend bool operator!=(const other_allocator& x, const other_allocator& y)
         {return !(x == y);}

     typedef std::true_type propagate_on_container_copy_assignment;
     typedef std::true_type propagate_on_container_move_assignment;
     typedef std::true_type propagate_on_container_swap;

 #ifdef _LIBCPP_HAS_NO_ADVANCED_SFINAE
     std::size_t max_size() const
         {return UINT_MAX / sizeof(T);}
 #endif  // _LIBCPP_HAS_NO_ADVANCED_SFINAE

 };

 #if TEST_STD_VER >= 11

 struct Ctor_Tag {};

 template <typename T> class TaggingAllocator;

 struct Tag_X {
   // All constructors must be passed the Tag type.

   // DefaultInsertable into vector<X, TaggingAllocator<X>>,
   Tag_X(Ctor_Tag) {}
   // CopyInsertable into vector<X, TaggingAllocator<X>>,
   Tag_X(Ctor_Tag, const Tag_X&) {}
   // MoveInsertable into vector<X, TaggingAllocator<X>>, and
   Tag_X(Ctor_Tag, Tag_X&&) {}

   // EmplaceConstructible into vector<X, TaggingAllocator<X>> from args.
   template<typename... Args>
   Tag_X(Ctor_Tag, Args&&...) { }

   // not DefaultConstructible, CopyConstructible or MoveConstructible.
   Tag_X() = delete;
   Tag_X(const Tag_X&) = delete;
   Tag_X(Tag_X&&) = delete;

   // CopyAssignable.
   Tag_X& operator=(const Tag_X&) { return *this; }

   // MoveAssignable.
   Tag_X& operator=(Tag_X&&) { return *this; }

 private:
   // Not Destructible.
   ~Tag_X() { }

   // Erasable from vector<X, TaggingAllocator<X>>.
   friend class TaggingAllocator<Tag_X>;
 };


 template<typename T>
 class TaggingAllocator {
 public:
     using value_type = T;
     TaggingAllocator() = default;

     template<typename U>
       TaggingAllocator(const TaggingAllocator<U>&) { }

     T* allocate(std::size_t n) { return std::allocator<T>{}.allocate(n); }

     void deallocate(T* p, std::size_t n) { std::allocator<T>{}.deallocate(p, n); }

     template<typename... Args>
     void construct(Tag_X* p, Args&&... args)
     { ::new((void*)p) Tag_X(Ctor_Tag{}, std::forward<Args>(args)...); }

     template<typename U, typename... Args>
     void construct(U* p, Args&&... args)
     { ::new((void*)p) U(std::forward<Args>(args)...); }

     template<typename U, typename... Args>
     void destroy(U* p)
     {
         p->~U();
         ((void)p); // Prevent MSVC's spurious unused warning
     }
 };

 template<typename T, typename U>
 bool
 operator==(const TaggingAllocator<T>&, const TaggingAllocator<U>&)
 { return true; }

 template<typename T, typename U>
 bool
 operator!=(const TaggingAllocator<T>&, const TaggingAllocator<U>&)
 { return false; }
 #endif


 #endif  // TEST_ALLOCATOR_H
	//===----------------------------------------------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is dual licensed under the MIT and the University of Illinois Open
	// Source Licenses. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#ifndef TEST_ALLOCATOR_H
	#define TEST_ALLOCATOR_H

	#include <cstddef>
	#include <type_traits>
	#include <cstdlib>
	#include <new>
	#include <climits>
	#include <cassert>

	#include "test_macros.h"

	class test_alloc_base
	{
	protected:
	static int time_to_throw;
	public:
	static int throw_after;
	static int count;
	static int alloc_count;
	};

	int test_alloc_base::count = 0;
	int test_alloc_base::time_to_throw = 0;
	int test_alloc_base::alloc_count = 0;
	int test_alloc_base::throw_after = INT_MAX;

	template <class T>
	class test_allocator
	: public test_alloc_base
	{
	int data_;

	template <class U> friend class test_allocator;
	public:

	typedef unsigned size_type;
	typedef int difference_type;
	typedef T value_type;
	typedef value_type* pointer;
	typedef const value_type* const_pointer;
	typedef typename std::add_lvalue_reference<value_type>::type reference;
	typedef typename std::add_lvalue_reference<const value_type>::type const_reference;

	template <class U> struct rebind {typedef test_allocator<U> other;};

	test_allocator() throw() : data_(0) {++count;}
	explicit test_allocator(int i) throw() : data_(i) {++count;}
	test_allocator(const test_allocator& a) throw()
	: data_(a.data_) {++count;}
	template <class U> test_allocator(const test_allocator<U>& a) throw()
	: data_(a.data_) {++count;}
	~test_allocator() throw() {assert(data_ >= 0); --count; data_ = -1;}
	pointer address(reference x) const {return &x;}
	const_pointer address(const_reference x) const {return &x;}
	pointer allocate(size_type n, const void* = 0)
	{
	assert(data_ >= 0);
	if (time_to_throw >= throw_after) {
	#ifndef _LIBCPP_NO_EXCEPTIONS
	throw std::bad_alloc();
	#else
	std::terminate();
	#endif
	}
	++time_to_throw;
	++alloc_count;
	return (pointer)::operator new(n * sizeof(T));
	}
	void deallocate(pointer p, size_type)
	{assert(data_ >= 0); --alloc_count; ::operator delete((void*)p);}
	size_type max_size() const throw()
	{return UINT_MAX / sizeof(T);}
	#if TEST_STD_VER < 11
	void construct(pointer p, const T& val)
	{::new(static_cast<void*>(p)) T(val);}
	#else
	template <class U> void construct(pointer p, U&& val)
	{::new(static_cast<void*>(p)) T(std::forward<U>(val));}
	#endif
	void destroy(pointer p)
	{
	p->~T();
	((void)p); // Prevent MSVC's spurious unused warning
	}
	friend bool operator==(const test_allocator& x, const test_allocator& y)
	{return x.data_ == y.data_;}
	friend bool operator!=(const test_allocator& x, const test_allocator& y)
	{return !(x == y);}
	};

	template <class T>
	class non_default_test_allocator
	: public test_alloc_base
	{
	int data_;

	template <class U> friend class non_default_test_allocator;
	public:

	typedef unsigned size_type;
	typedef int difference_type;
	typedef T value_type;
	typedef value_type* pointer;
	typedef const value_type* const_pointer;
	typedef typename std::add_lvalue_reference<value_type>::type reference;
	typedef typename std::add_lvalue_reference<const value_type>::type const_reference;

	template <class U> struct rebind {typedef non_default_test_allocator<U> other;};

	// non_default_test_allocator() throw() : data_(0) {++count;}
	explicit non_default_test_allocator(int i) throw() : data_(i) {++count;}
	non_default_test_allocator(const non_default_test_allocator& a) throw()
	: data_(a.data_) {++count;}
	template <class U> non_default_test_allocator(const non_default_test_allocator<U>& a) throw()
	: data_(a.data_) {++count;}
	~non_default_test_allocator() throw() {assert(data_ >= 0); --count; data_ = -1;}
	pointer address(reference x) const {return &x;}
	const_pointer address(const_reference x) const {return &x;}
	pointer allocate(size_type n, const void* = 0)
	{
	assert(data_ >= 0);
	if (time_to_throw >= throw_after) {
	#ifndef _LIBCPP_NO_EXCEPTIONS
	throw std::bad_alloc();
	#else
	std::terminate();
	#endif
	}
	++time_to_throw;
	++alloc_count;
	return (pointer)::operator new (n * sizeof(T));
	}
	void deallocate(pointer p, size_type)
	{assert(data_ >= 0); --alloc_count; ::operator delete((void*)p); }
	size_type max_size() const throw()
	{return UINT_MAX / sizeof(T);}
	#if TEST_STD_VER < 11
	void construct(pointer p, const T& val)
	{::new(static_cast<void*>(p)) T(val);}
	#else
	template <class U> void construct(pointer p, U&& val)
	{::new(static_cast<void*>(p)) T(std::forward<U>(val));}
	#endif
	void destroy(pointer p) {p->~T();}

	friend bool operator==(const non_default_test_allocator& x, const non_default_test_allocator& y)
	{return x.data_ == y.data_;}
	friend bool operator!=(const non_default_test_allocator& x, const non_default_test_allocator& y)
	{return !(x == y);}
	};

	template <>
	class test_allocator<void>
	: public test_alloc_base
	{
	int data_;

	template <class U> friend class test_allocator;
	public:

	typedef unsigned size_type;
	typedef int difference_type;
	typedef void value_type;
	typedef value_type* pointer;
	typedef const value_type* const_pointer;

	template <class U> struct rebind {typedef test_allocator<U> other;};

	test_allocator() throw() : data_(0) {}
	explicit test_allocator(int i) throw() : data_(i) {}
	test_allocator(const test_allocator& a) throw()
	: data_(a.data_) {}
	template <class U> test_allocator(const test_allocator<U>& a) throw()
	: data_(a.data_) {}
	~test_allocator() throw() {data_ = -1;}

	friend bool operator==(const test_allocator& x, const test_allocator& y)
	{return x.data_ == y.data_;}
	friend bool operator!=(const test_allocator& x, const test_allocator& y)
	{return !(x == y);}
	};

	template <class T>
	class other_allocator
	{
	int data_;

	template <class U> friend class other_allocator;

	public:
	typedef T value_type;

	other_allocator() : data_(-1) {}
	explicit other_allocator(int i) : data_(i) {}
	template <class U> other_allocator(const other_allocator<U>& a)
	: data_(a.data_) {}
	T* allocate(std::size_t n)
	{return (T)::operator new(n sizeof(T));}
	void deallocate(T* p, std::size_t)
	{::operator delete((void*)p);}

	other_allocator select_on_container_copy_construction() const
	{return other_allocator(-2);}

	friend bool operator==(const other_allocator& x, const other_allocator& y)
	{return x.data_ == y.data_;}
	friend bool operator!=(const other_allocator& x, const other_allocator& y)
	{return !(x == y);}

	typedef std::true_type propagate_on_container_copy_assignment;
	typedef std::true_type propagate_on_container_move_assignment;
	typedef std::true_type propagate_on_container_swap;

	#ifdef _LIBCPP_HAS_NO_ADVANCED_SFINAE
	std::size_t max_size() const
	{return UINT_MAX / sizeof(T);}
	#endif // _LIBCPP_HAS_NO_ADVANCED_SFINAE

	};

	#if TEST_STD_VER >= 11

	struct Ctor_Tag {};

	template <typename T> class TaggingAllocator;

	struct Tag_X {
	// All constructors must be passed the Tag type.

	// DefaultInsertable into vector<X, TaggingAllocator<X>>,
	Tag_X(Ctor_Tag) {}
	// CopyInsertable into vector<X, TaggingAllocator<X>>,
	Tag_X(Ctor_Tag, const Tag_X&) {}
	// MoveInsertable into vector<X, TaggingAllocator<X>>, and
	Tag_X(Ctor_Tag, Tag_X&&) {}

	// EmplaceConstructible into vector<X, TaggingAllocator<X>> from args.
	template<typename... Args>
	Tag_X(Ctor_Tag, Args&&...) { }

	// not DefaultConstructible, CopyConstructible or MoveConstructible.
	Tag_X() = delete;
	Tag_X(const Tag_X&) = delete;
	Tag_X(Tag_X&&) = delete;

	// CopyAssignable.
	Tag_X& operator=(const Tag_X&) { return *this; }

	// MoveAssignable.
	Tag_X& operator=(Tag_X&&) { return *this; }

	private:
	// Not Destructible.
	~Tag_X() { }

	// Erasable from vector<X, TaggingAllocator<X>>.
	friend class TaggingAllocator<Tag_X>;
	};


	template<typename T>
	class TaggingAllocator {
	public:
	using value_type = T;
	TaggingAllocator() = default;

	template<typename U>
	TaggingAllocator(const TaggingAllocator<U>&) { }

	T* allocate(std::size_t n) { return std::allocator<T>{}.allocate(n); }

	void deallocate(T* p, std::size_t n) { std::allocator<T>{}.deallocate(p, n); }

	template<typename... Args>
	void construct(Tag_X* p, Args&&... args)
	{ ::new((void*)p) Tag_X(Ctor_Tag{}, std::forward<Args>(args)...); }

	template<typename U, typename... Args>
	void construct(U* p, Args&&... args)
	{ ::new((void*)p) U(std::forward<Args>(args)...); }

	template<typename U, typename... Args>
	void destroy(U* p)
	{
	p->~U();
	((void)p); // Prevent MSVC's spurious unused warning
	}
	};

	template<typename T, typename U>
	bool
	operator==(const TaggingAllocator<T>&, const TaggingAllocator<U>&)
	{ return true; }

	template<typename T, typename U>
	bool
	operator!=(const TaggingAllocator<T>&, const TaggingAllocator<U>&)
	{ return false; }
	#endif


	#endif // TEST_ALLOCATOR_H